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Department of Electronics and
Instrumentation Engineering
M.Tech. Industrial Automation
Curriculum & Syllabus 2014 Regulations
Page 1 of 43
ACADEMIC REGULATIONS (M.TECH./ M.B.A. / M.C.A.) (Full - Time / Part – Time) (Effective 2014-15) 1. Vision, Mission and Objectives 1.1 The Vision of the Institute is “To make every man a success and no man a failure”.
In order to progress towards the vision, the Institute has identified itself with a mission to provide every individual with a conducive environment suitable to achieve his / her career goals, with a strong emphasis on personality development, and to offer quality education in all spheres of engineering, technology, applied sciences and management, without compromising on the quality and code of ethics. 1.2 Further, the institute always strives
To train our students with the latest and the best in the rapidly changing fields of Engineering, Technology, Management, Science & Humanities.
To develop the students with a global outlook possessing, state of the art skills, capable of taking up challenging responsibilities in the respective fields.
To mould our students as citizens with moral, ethical and social values so as to fulfill their obligations to the nation and the society.
To promote research in the field of science, Humanities, Engineering, Technology and allied branches.
1.3 Our aims and objectives are focused on
Providing world class education in engineering, technology, applied science and management.
Keeping pace with the ever changing technological scenario to help our students to gain proper direction to emerge as competent professionals fully aware of their commitment to the society and nation.
To inculcate a flair for research, development and entrepreneurship.
2. Admission
2.1. The admission policy and procedure shall be decided from time to time by the Board of Management (BOM) of the Institute, following guidelines issued by Ministry of Human Resource Development (MHRD), Government of India. The number of seats in each branch of the (M.TECH / M.B.A. / M.C.A.) programme will be decided by BOM as per the directives from Ministry of Human Resource Development (MHRD), Government of India and taking into account the market demands. Some seats for Non Resident Indians and a few seats for foreign nationals shall be made available.
2.2. The selected candidates will be admitted to the (M.TECH / M.B.A. / M.C.A.) programme after he/she fulfills all the admission requirements set by the Institute and after payment of the prescribed fees.
2.3. Candidates for admission to the first semester of the Master‟s Degree Programme shall be required to have passed an appropriate Degree Examination recognized by Hindustan University. 2.4. In all matters relating to admission to the (M.TECH /M.B.A. / M.C.A.).
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Programme, the decision of the Institute and its interpretation given by the Chancellor of the Institute shall be final.
2.5. If at any time after admission, it is found that a candidate has not fulfilled any of the requirements stipulated by the Institute, the Institute may revoke the admission of the candidate with information to the Academic Council.
3. Structure of the programme
3.1. The programme of instruction will have the following structure i) Core courses of Engineering / Technology
/ Management. ii) Elective courses for specialization in
areas of student‟s choice.
3.2. The minimum durations of the programmes are as given below:
Program No. of
Semesters
M.Tech.(Full-Time) 4
M.Tech.(Part -Time) 6
M.B.A. (Full - Time) 4
M.B.A. (Part - Time) 6
M.C.A.(Full - Time) 6
M.C.A.(Part -Time) 8
Every (M.TECH / M.B.A. / M.C.A.) programme will have a curriculum and syllabi for the courses approved by the Academic Council.
3.3. Each course is normally assigned
certain number of credits. The following norms will generally be followed in assigning credits for courses.
One credit for each lecture hour per week per semester;
One credit for each tutorial hour per week per semester;
One credit for each laboratory practical (drawing) of three (two) hours per week per semester.
One credit for 4 weeks of industrial training and
One credit for 2 hours of project per week per semester.
3.4. For the award of degree, a student has to earn certain minimum total number of credits specified in the curriculum of the relevant branch of study. The curriculum of the different programs shall be so designed that the minimum prescribed credits required for the award of the degree shall be within the limits specified below.
Program
Minimum prescribed
credit range
M.Tech. (Full time / Part time)
75 - 85
M.B.A. (Full time / Part time)
85 - 95
M.C.A (Full time / Part time)
115 - 125
3.5. The medium of instruction, examination and the language of the project reports will be English.
4. Faculty Advisor
4.1. To help the students in planning their courses of study and for getting general advice on the academic programme, the concerned Department will assign a certain number of students to a Faculty member who will be called their Faculty Advisor. 5. Class Committee
5.1 A Class Committee consisting of the following will be constituted by the Head of the Department for each class:
(i) A Chairman, who is not teaching the
class.
(ii) All subject teachers of the class.
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(iii)Two students nominated by the
department in consultation with the
class.
The Class Committee will meet as often as necessary, but not less than three times during a semester.
The functions of the Class Committee will include: (i) Addressing problems experienced by
students in the classroom and the laboratories.
(ii) Analyzing the performance of the
students of the class after each test and finding ways and means of addressing problems, if any.
(iii) During the meetings, the student members shall express the opinions and suggestions of the class students to improve the teaching / learning process.
6. Grading 6.1 A grading system as below will be adhered to. 6.2 GPA & CGPA GPA is the ratio of the sum of the product of the number of credits Ci of course “i “ and the grade points Pi earned for that course taken over all courses “i”
registered by the student to the sum of Ci for all “i ”. That is,
ii
iii
C
PC
GPA
CGPA will be calculated in a similar manner, at any semester, considering all the courses enrolled from first semester onwards. 6.3. For the students with letter grade I in certain subjects, the same will not be included in the computation of GPA and CGPA until after those grades are converted to the regular grades. 6.4 Raw marks will be moderated by a moderation board appointed by the Vice Chancellor of the University. The final marks will be graded using an absolute grading system. The Constitution and composition of the moderation board will be dealt with separately. 7. Registration and Enrollment
7.1 Except for the first semester, registration and enrollment will be done in the beginning of the semester as per the schedule announced by the University.
7.2 A student will be eligible for enrollment only if he/she satisfies regulation 10 (maximum duration of the programme) and will be permitted to enroll if (i) he/she has cleared all dues in the Institute, Hostel & Library up to the end of the previous semester and (ii) he/she is not debarred from enrollment by a disciplinary action of the University.
7.3. Students are required to submit registration form duly filled in. 8. Registration requirement
8.1. (i) A Full time student shall not register for less than 16 credits or more than 26 credits in any given semester.
Range of Marks
Letter Grade Grade points
95-100 S 10
85 - 94 A 09
75- 84 B 08
65-74 C 07
55-64 D 06
50-54 E 05
< 50 U 00
I (Incomplete) --
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8.1. (ii) A part time student shall not register for less than 10 credits or more than 20 credits in any given semester.
8.2 If a student finds his/her load heavy in any semester, or for any other valid reason, he/she may withdraw from the courses within three weeks of the commencement of the semester with the written approval of his/her Faculty Advisor and HOD. However the student should ensure that the total number of credits registered for in any semester should enable him/her to earn the minimum number of credits per semester for the completed semesters. 9. Minimum requirement to continue the programme
9.1. For those students who have not earned the minimum required credit prescribed for that particular semester examination, a warning letter to the concerned student and also to his parents regarding the shortage of his credit will be sent by the HOD after the announcement of the results of the university examinations.
10. Maximum duration of the programme
The minimum and maximum period for the completion of various programs are given below.
Program
Min. No. of
Semesters
Max. No. of
Semesters
M.Tech (Full - time)
4 8
M.Tech (Part - time)
6 10
M.B.A. (Full Time)
4 8
M.B.A. (Part Time)
6 10
M.C.A. (Full - Time)
6 12
M.C.A 8 14
(Part –Time)
11. Temporary discontinuation 11.1. A student may be permitted by the Director(Academic) to discontinue temporarily from the programme for a semester or a longer period for reasons of ill health or other valid reasons. Normally a student will be permitted to discontinue from the programme only for a maximum duration of two semesters. 12. Discipline 12.1. Every student is required to observe discipline and decorum both inside and outside the campus and not to indulge in any activity which will tend to bring down the prestige of the University. 12.2. Any act of indiscipline of a student reported to the Director(Academic) will be referred to a Discipline Committee so constituted. The Committee will enquire into the charges and decide on suitable punishment if the charges are substantiated. The committee will also authorize the Director(Academic) to recommend to the Vice - Chancellor the implementation of the decision. The student concerned may appeal to the Vice Chancellor whose decision will be final. The Director(Academic) will report the action taken at the next meeting of the Council. 12.3. Ragging and harassment of women are strictly prohibited in the University campus and hostels. 13. Attendance 13.1. A student whose attendance is less than 75% is not eligible to appear for the end semester examination for that semester. The details of all students who have attendance less than 75% will be announced by the teacher in the class. These details will be sent to the concerned HODs and Dean.
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13.2. Those who have less than 75% attendance will be considered for condonation of shortage of attendance. However a condonation of 10% in attendance will be given on medical reasons. Application for condonation recommended by the Faculty Advisor, concerned faculty member and the HOD is to be submitted to the Director(Academic) who, depending on the merits of the case, may permit the student to appear for the end semester examination. A student will be eligible for this concession at most in two semesters during the entire degree programme. Application for medical leave, supported by medical certificate with endorsement by a Registered Medical Officer, should reach the HOD within seven days after returning from leave or, on or before the last instructional day of the semester, whichever is earlier. 13.3. As an incentive to those students who are involved in extra curricular activities such as representing the University in Sports and Games, Cultural Festivals, and Technical Festivals, NCC/ NSS events, a relaxation of up to 10% attendance will be given subject to the condition that these students take prior approval from the officer –in-charge. All such applications should be recommended by the concerned HOD and forwarded to Director(Academic) within seven instructional days after the programme/activity. 14. Assessment Procedure 14.1. The Academic Council will decide from time to time the system of tests and examinations in each subject in each semester. 14.2. For each theory course, the assessment will be done on a continuous basis as follows:
Test / Exam Weightage
Duration of Test /
Exam
First Periodical Test*
10% 2 Periods
Second Periodical Test*
10% 2 Periods
Model exam 20% 3 hours
Seminar/ Assignments/Quiz
20%
End – semester examination
50% 3 Hours
* Best out of the two tests will be considered. 14.3. For practical courses, the assessment will be done by the subject teachers as below: (i) Weekly assignment/Observation note book / lab records – weightage 60%. (ii) End semester examination of 3 hours duration including viva – weightage 40%. 15. Make up Examination/model examination 15.1. Students who miss the end-semester examinations / model examination for valid reasons are eligible for make-up examination /model examination. Those who miss the end-semester examination / model examination should apply to the Head of the Department concerned within five days after he / she missed examination, giving reasons for absence. 15.2 Permission to appear for make-up examination / model exam will be given under exceptional circumstances such as admission to a hospital due to illness. Students should produce a medical certificate issued by a Registered Medical Practitioner certifying that he/she was admitted to hospital during the period of examination / model exam and the same should be duly endorsed by parent / guardian and also by a medical officer of the University within 5 days.
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16. Project evaluation 16.1. For Project work, the assessment will be done on a continuous basis as follows:
Review / Examination Weightage
First Review 10%
Second Review 20%
Third Review 20%
End semester Examination
50%
For end semester exam, the student will submit a Project Report in a format specified by the Director(Academic). The first three reviews will be conducted by a Committee constituted by the Head of the Department. The end – semester examination will be conducted by a Committee constituted by the Controller of Examinations. This will include an external expert. 17. Declaration of results 17.1 A candidate who secures not less than 50% of total marks prescribed for a course with a minimum of 50% of the marks prescribed for the end semester examination shall be declared to have passed the course and earned the specified credits for the course. 17.2 After the valuation of the answer scripts, the tabulated results are to be scrutinized by the Result Passing Boards of PG programmes constituted by the Vice-Chancellor. The recommendations of the Result Passing Boards will be placed before the Standing Sub Committee of the Academic Council constituted by the Chancellor for scrutiny. The minutes of the Standing Sub Committee along with the results are to be placed before the Vice-Chancellor for approval. After getting the approval of the Vice-
Chancellor, the results will be published by the Controller of Examination/Registrar. 17.3 If a candidate fails to secure a pass in a course due to not satisfying the minimum requirement in the end semester examination, he/she shall register and re-appear for the end semester examination during the following semester. However, the sessional marks secured by the candidate will be retained for all such attempts. 17.4 If a candidate fails to secure a pass in a course due to insufficient sessional marks though meeting the minimum requirements of the end semester examination, wishes to improve on his/her sessional marks, he/she will have to register for the particular course and attend the course with permission of the HOD concerned and the Registrar. The sessional and external marks obtained by the candidate in this case will replace the earlier result. 17.5 A candidate can apply for the revaluation of his/her end semester examination answer paper in a theory course within 2 weeks from the declaration of the results, on payment of a prescribed fee through proper application to the Registrar/Controller of Examinations through the Head of the Department. The Registrar/ Controller of Examination will arrange for the revaluation and the results will be intimated to the candidate concerned through the Head of the Department. Revaluation is not permitted for practical courses and for project work. 18. Grade Card 18.1. After results are declared, grade sheet will be issued to each student, which will contain the following details:
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(i) Program and branch for which the student has enrolled.
(ii) Semester of registration. (iii) List of courses registered during
the semester and the grade scored.
(iv) Semester Grade Point Average (GPA)
(v) Cumulative Grade Point Average (CGPA).
19. Class / Division
19.1 Classification is based on CGPA and is as follows: CGPA≥8.0: First Class with distinction 6.5 ≤CGPA < 8.0: First Class 5.0 ≤CGPA < 6.5: Second Class. 19.2 (i) Further, the award of „First class with distinction‟ is subject to the candidate becoming eligible for the award of the degree having passed the examination in all the courses in his/her first appearance within the minimum duration of the programme. (ii) The award of „First Class‟ is further subject to the candidate becoming eligible to the award of the degree having passed the examination in all the courses within the below mentioned duration of the programme.
Program No. of
Semesters
M.Tech (Full - time)
5
M.Tech (Part - time)
7
M.B.A. (Full Time)
5
M.B.A. (Part Time)
7
M.C.A. (Full - Time)
7
M.C.A (Part –Time)
9
(iii) The period of authorized discontinuation of the programme (vide clause 11.1) will not be counted for the purpose of the above classification. 20. Transfer of credits 20.1. Within the broad framework of these regulations, the Academic Council, based on the recommendation of the transfer of credits committee so constituted by the Chancellor may permit students to earn part of the credit requirement in other approved institutions of repute and status in the country or abroad.
21. Eligibility for the award of (M.TECH / M.B.A. / M.C.A.) Degree 21.1. A student will be declared to be eligible for the award of the (M.TECH / M.B.A. / M.C.A.) Degree if he/she has
i) registered and successfully credited all the core courses,
ii) successfully acquired the credits in the different categories as specified in the curriculum corresponding to the discipline (branch) of his/her study within the stipulated time,
iii) has no dues to all sections of the Institute including Hostels, and
iv) has no disciplinary action pending against him/her.
The award of the degree must be recommended by the Academic Council and approved by the Board of Management of the University. 22. Power to modify 22.1. Notwithstanding all that has been stated above, the Academic Council has the right to modify any of the above regulations from time to time subject to approval by the Board of Management.
Page 1 of 43
M.TECH. - INDUSTRIAL AUTOMATION
CURRICULUM 2014-2015
SEMESTER I
S.No Course
Code Course Title L T P C TCH
Theory
1. PMA106 Advanced Applied Mathematics * 3 1 0 4 4
2. PPC101 Analog and Digital Instrumentation 3 1 0 4 4
3. PPC102 Transducer Design 3 1 0 4 4
4. PES102 Embedded System Design# 3 1 0 4 4
5. PPC103 Communication Protocols for
Instrumentation 3 1 0 4 4
6. PVL102 Real Time Operating System** 3 1 0 4 4
Practical
7. PPC104 Embedded System Design Laboratory 0 0 3 1 3
Total 25 27
*---Common to M.Tech (ES/PCI/CS/AE/CCE/VLSI)
#---Common to M.Tech (CS/ES/VLSI/PC&I/AE/EC)
**---Common to M.Tech (ES/PCI/EC)
SEMESTER II
S.No Course
Code Course Title L T P C TCH
Theory
1. PPD204 Linear and Non-Linear System
Theory* 3 1 0 4 4
2. PPC201 Programmable Logic Controller &
Distributed Control Systems 3 1 0 4 4
3. PIA 201 Advanced Control System 3 1 0 4 4
4. PIA202 Intelligent Control 3 1 0 4 4
5 PIA203 Industrial Automation and Robotics 3 1 0 4 4
6. PIA204 Process Dynamics and Control 3 1 0 4 4
Practical
7. PIA 211 Expert Systems Laboratory 0 0 3 1 3
PIA212 Industrial Automation and Robotics
Laboratory 0 0 3 1 3
Total 26 30 *---Common to M.Tech (PCI/PED)
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SEMESTER III
S.No Course
Code Course Title L T P C TCH
Theory
1. PIA3xx Elective - I 3 1 0 4 4
2. PIA3xx Elective – II 3 1 0 4 4
3. PIA3xx Elective - III 3 1 0 4 4
Practical
4. PIA305 Project Phase- I 0 0 12 6 12
Total 18 24
List of Electives
Elective - I
S.No Course
Code Course Title L T P C TCH
1. PIA321 SCADA Systems and Applications 3 1 0 4 4
2. PIA322 Data Acquisition Systems 3 1 0 4 4
3. PIA323 Advanced Sensor Technology 3 1 0 4 4
Elective – II
S.No Course
Code Course Title L T P C TCH
Theory
1. PIA324 System Identification and Control 3 1 0 4 4
2. PIA325 Multi-Variable Control 3 1 0 4 4
3. PIA326 Fault Detection and Diagnosis 3 1 0 4 4
Elective - III
S.No Course
Code Course Title L T P C TCH
Theory
1. PIA327 Computer Control of Manufacturing Systems 3 1 0 4 4
2. PIA328 Mechatronics in manufacturing Systems 3 1 0 4 4
3. PIA329 Process Consulting And Project Planning 3 1 0 4 4
4. PIA330 Advanced Adaptive Control Systems 3 1 0 4 4
SEMESTER IV
S.No Course
Code Course Title L T P C TCH
Practical
1. PIA406 Project Phase-II 0 0 24 12 24
Total 12 24
Total Credits: 81
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SEMESTER I
[Common to M.Tech (ES/PCI/CS/AE/CCE and VLSI)]
PMA106 ADVANCED APPLIED MATHEMATICS
4 Credits
Goal Develop the Mathematical skills to formulate certain practical problems, solve them and
physically interpret the results
Objectives Outcomes
The course should enable the student to
1. Understand the techniques to solve the
system of equations using direct
method and indirect methods. Learns
to decompose the matrix in the LU
form and to find the Eigen value of a
matrix using power and Jacobi
methods.
2. Learn to classify the initial and
boundary value problems. Understands
the D'Alemberts solution of the one
dimensional wave equation. Learn
significance of characteristic curves.
3. Learn series solutions of Bessel‟s and
Legendre equations. Understand
recurrence relation, generating
functions and orthogonal properties.
4. Learn basics of probability, addition
and multiplication, Baye‟s theorems.
Understands the concept of random
variable, moment generating function
and their properties. Learn standard
distributions in discrete and continuous
cases
5. Learns the different Markovian models
with finite and infinite capacity and
understands to classify them.
The students should be able to:
1. Able to write the algorithm for solving the simultaneous
equations for direct and indirect methods. Identifies the
Eigen values using conventional method and compares
with numerical solutions. Able to write the algorithm to
find the Eigen values of a matrix.
2. Able to form the wave equations with initial conditions
and solve them using D'Alemberts solutions. Solves the
wave equations using Laplace transform for
displacements in long string – long string under its
weight and free and forced vibrations.
3. Solves the Bessel‟s equation and Legendre equations.
Using Bessel‟s function solves many practical problems
that arise in electrical transmission problems and
vibration of membranes as in loudspeakers.
4. Evaluates the probability using addition and
multiplication theorem. Applies Baye‟sfor practical
problems to find the probability. Verifies whether a
given function is a probability mass or density function.
Applies the discrete and continuous distributions for
solving practical problems. Evaluates the moments of
the distributions using moment generating function.
5. Able to analyze and classify the models, M / M / 1, M /
M / C, finite and infinite capacity and solves practical
problems related to the queuing models.
UNIT-I: - LINEAR ALGEBRAIC EQUATION AND EIGEN VALUE PROBLEMS
12
System of Equations – Solution by Gauss Elimination and Gauss Jordan methods – LU decomposition
method – Indirect methods – Gauss Jacobi and Gauss Seidel methods – Eigen values of a matrix using Jacobi
and power methods.
UNIT-II: - WAVE EQUATION 12
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Solution of initial and boundary value problems - Characteristics - D'Alembert's solution - Significance of
characteristic curves - Laplace transform solutions for displacement in a long string, in a long string under its
weight - a bar with prescribed force on one end - Free vibrations of a string.
UNIT-III: - SPECIAL FUNCTIONS 12
Series solutions - Bessel's equation - Bessel functions - Legendre's equation - Legendre polynomials -
Rodrigue's formula - Recurrence relations - Generating functions and orthogonal property for Bessel
functions of the first kind - Legendre polynomials.
UNIT-IV: - PROBABILITY AND RANDOM VARIABLE 12
Discrete and Continuous random variables – Moments – Moment generating functions - Standard
distributions - Binomial, Poisson, Geometric, Negative Binomial, Uniform, Normal ,Exponential, Gamma
and Weibull distributions – Two dimensional random variables – Joint, Marginal and Conditional
distributions. Correlation and Regression.
UNIT-V: - QUEUING THEORY 12
Markovian models – Birth and death queuing models – Steady state – Single and Multiple servers – M/M/1 –
Finite and infinite capacity – M/M/C – finite and infinite capacity.
L = 45 T = 15 TOTAL: 60
REFERENCE BOOK
1) Taha, H.A., “Operations Research - An Introduction ", Prentice Hall of India Ltd., 6th Edition, New
Delhi, 1997.
2) Dr.Singaravelu A., Dr.Siva Subramanian S., and Dr.Ramachandran C., “Probability and Queuing
Theory”, Meenakshi agency, 20th edition, January 2013.
3) Veerarajan T., “Probability, Statistics and Random Processes”, Tata McGraw-Hill, second edition,
2004.
4) Grewal B.S., “Higher Engineering Mathematics”, Khanna Publishers, 34th edition.
5) Sankara Rao K., “Introduction to Partial Differential Equations”, PHI, 1995.
6) Veerarajan T., “Mathematics IV”, Tata McGraw-Hill, 2000.
PPC101 ANALOG AND DIGITAL INSTRUMENTATION 4 CREDITS
Goal The goal of the programme is to provide a thorough knowledge about different types of Data
Acquisition systems and about different communication systems used in industry.
Objectives Outcome
The course should enable the students :
1. To study the different type of A/D converters.
2. To make them understand the building blocks
of Automation systems and various Data
Acquisition Systems& Data loggers.
3. To assist the learners in understanding about
different types of interfacing and transmission
systems.
4. To learn the different types of communication
protocols such as HART, Field bus, General
Field bus architecture, Instrumentation buses,
Mod bus, GPIB, Network buses, Ethernet,
The students should be able to:
1. The learners will have the confidence on how to
select the A/D converter for different application.
2. The learners will be able to know the difference
between single channel and multi-channelData
Acquisition Systems and can use this knowledge in
sensor based acquisition systems.
3. The learners will be able to understand TDM,
Digital Modulation, Pulse Modulation and different
interfacing system standards.
4. The learners will be able to understand the different
communication protocols that industries are
Page 5 of 43
TCP/IP protocols.
5. Tolearn the real time Data Acquisition system
applications for the case studies.
following.
5. The learners will have the basic idea of PC based
industrial process measurements like flow,
temperature, pressure and level systems.
UNIT-I: - BASIC BLOCKS 12
Overview of A/D converter, types and characteristics-Understanding Data acquisition, A/D and S/H
terms-passive support and Active support components-Single and Multi-slope, Low cost A/D conversion
techniques, types-Electromechanical A/D converter.
UNIT-II: - DATA ACQUISITION SYSTEMS 12
Objective - Building blocks of Automation systems – Multi, Single channel Data Acquisition
systems, PC based DAS, Data loggers- Sensors based computer data systems.
UNIT-III: - INTERFACING AND DATA TRANSMISSION 12
Data transmission systems- 8086 Microprocessor based system design - Peripheral Interfaces – Time
Division Multiplexing (TDM) – Digital Modulation – Pulse Modulation – Pulse Code Format – Interface
systems and standards – Communications.
UNIT-IV: - PC BASED INSTRUMENTATION 12
Introduction - Evolution of signal Standard - HART Communication protocol -Communication
modes - HART networks - control system interface - HART commands -HART field controller
implementation - HART and the OSI model - Field bus –Introduction - General field bus architecture - Basic
requirements of field bus standard -field bus topology - Interoperability –Interchangeability - Instrumentation
buses-Mod bus - GPIB - Network buses – Ethernet - TCP/IP protocols
UNIT-V: - CASE STUDIES 12
PC based industrial process measurements like flow, temperature, pressure and level – PC based
instruments development system.
L = 45 T = 15 TOTAL: 60
REFERENCE BOOK
1. Kevin M. Daugherty, “Analog – to – Digital conversion – A Practical Approach”, McGraw Hill
International Editions, 1995
2. N. Mathivanan, “Microprocessors, PC Hardware and Interfacing”, Prentice – Hall of India Pvt.
Ltd., 2003.
3. Krishna Kant “Computer- based Industrial Control”, Prentice- Hall of India Pvt. Ltd., 2004.
4. H S. Kalsi, “Electronic Instrumentation”, Technical Education Series Tata McGraw-Hill, 2004.
5. Buchanan, “Computer busses”, Arnold, London, 2000.
PPC102 TRANSDUCER DESIGN 4 CREDITS
Goal To provide basic knowledge about various sensors, its selection criteria and their Applications
Objectives Outcome
Page 6 of 43
The course will enable the students :
1. To impart knowledge about the various sensors used
for measuring physical parameters.
2. Emphasis on signal processing, converting and
presenting it to monitoring /controlling instruments.
3. To acquire knowledge design of electro mechanical
transducers for heavy machinery devices.
4. To acquaint them with various transducers used for
measurement in various environment.
The students should be able to:
1. Understand the basic principles of sensors
used for measuring physical parameters.
2. Design signal conditioning circuits and
monitor parameters.
3. To design/ select electro-mechanical
transducers used in air craft and ship
industries.
4. Choose and apply transducer for various
environments.
UNIT-I: - FUNDAMENTALS 12
Review of Fundamentals of Transducers for measurement of: Physical parameters like. Displacement,
Pressure, Force, Flow, Stress, Strain, Velocity, Vibration, Torque, Temperature, pH, Conductivity, Proximity
sensors, Chemical parameters, Biomedical parameters like. Pathological parameters, Detection of alpha, beta
and gamma radiation.
UNIT-II: - SIGNAL CONDITIONERS 12
Review of signal conditioners for: Strain Gauge Transducers, Inductive Transducers, Magnetic,
Magneto-strictest, Piezo Electric Transducers, Optical Transducers, Capacitive Transducers, Vibrating wire,
Review of Processors for Analog and Digital Signals, Review of Various Input and Output Display Systems
UNIT-III: - ELECTROMECHANICAL TRANSDUCERS 12
Design of Electromechanical Transducers for: Force, Pressure, Stress, Vibration using ,Strain-gauge,
LVDT , Capacitive Elements, Optical Device, Application in design case, such as measurements for
Hydraulic and Pneumatic Machinery like Turbines, Aircraft Systems and Ship Machinery
UNIT-IV: - SELECTION CRITERIA & APPLICATION 12
Discussion of Selection Criteria for each of above cases: Design of Electromechanical Transducers
for Torque, Flow and Velocity. Application in design case from Automobile for Torque, Liquid Flow for
Flow and Velocity. Inclination/Tilt, Rotation and Gyration of Machinery like Winches, Earth Movers, and
Fork lifts, Giant Wheels, Space Craft etc. Discussion on design criteria for three component and six
component dynamometers both pure mechanical and electromechanically designs. Discussion on Multi-
output (including digital) Transducers for various applications.
UNIT-V: - CASE STUDIES 12
Case Studies for: Chemical Sensors, Bio sensors, Gas Sensors. Discussions on Nano Sensors and
MEMS applications. Application of LASER for various measurements like: alignment, distance, velocimetry
for convection and liquid flow, angular rotation. Applications of LASER for micromachining, printing and
compact discs like CD and DVD, Weapons, welding, surface hardening, cutting, nuclear fusion.
L = 45 T = 15 Total = 60
REFERENCE BOOK
1. H K P Neubert, „Instrument Transducers‟, Oxford University Press, 1999
2. Bella G Liptak, „Instrument Engineers Handbook, Vol 1, 2 and 3‟, 4th edition, CRC Press, 2005.
3. C.S. Rangan, G.R. Sarma and V.S.V. Mani „Instrumentation Devices and Systems‟, Tata
McGraw-Hill Publishing Company Ltd. New Delhi, 2004.
4. J. Wilson, J.F.B. Hawkes, „Laser Principles and Applications‟, Prentice-Hall, New York, 1987.
5. J. Wilson, „Optoelectronics‟, 2nd Edition, Prentice-Hall, India. 2003.
Page 7 of 43
PES102 EMBEDDED SYSTEN DESIGN 4 CREDITS
Goal The aim of this course is to expose the concepts of Embedded system principles and software
development tools and introducing PIC and Motorola microcontrollers and interfacing.
Objectives Outcome
The course should enable the students to:
1. Understand the use of review in
embedded hardware.
2. Understand basic concepts of design
of Embedded software system,
3. Understand the Software architecture
and Developments tools
4. Understand the Operation of PIC
microcontroller and interfacing
5. Understand the Operation of
Embedded Microcomputer systems
At the end of the course the student should be able to:
1. Use of hardware fundamentals.Gates,timing
diagram,DMA,interrupts,built ins on the microprocessor and
microprocessor architecture.
2. Explain the concept of Tasks,States,Data,Semaphores,more
operating system servicesIR in RTOS environment,Basic
design using RTOS,
3. Develop through basic knowledge on the behavior and the
characteristics of Round-Robin
techniques,Functions,Queue,Host and Target machine and
Debugging techniques,
4. Learn the usage of Architecture,instruction sets of PIC, Loop
time subroutine,I/O port expansion,I2C for peripherals chip
access,ADC and UART special features,
5. Acquire knowledge on the configuration of
Motorola,Registers,addressing
modes,interfacingmethods,ISR,Timing generations and
measurements
.
.
UNIT-I: - INTRODUCTION: REVIEW OF EMBEDDED HARDWARE 12
Hardware Fundamentals: Terminology- Gates- Timing Diagram- Microprocessors- Buses- Direct Memory
Access- Interrupts- Other Common Parts- Built-Ins on the Microprocessor-Conventions Used on Schematics.
Interrupts: Microprocessor Architecture - Interrupts Basics-Shared-Data Problem- Interrupt Latency,
Examples of Embedded System.
UNIT-II: - DESIGN OF EMBEDDED SOFTWARE SYSTEM 12
Introduction: Tasks and Task States- Tasks and Data- Semaphores and Shared Data. More Operating System
Services: Message Queues- Mailboxes and Pipes- Timer Functions- Events- Memory Management- Interrupt
Routines in an RTOS Environment, Basic Design Using a Real-Time Operating System.
UNIT-III: - SOFTWARE ARCHITECTURES AND DEVELOPMENT AND TOOLS 12
Software Architectures: Round-Robin- Round-Robin with Interrupts- Function-Queue-Scheduling
Architecture- Real-Time Operating System Architecture, Development Tools: Host and Target Machines-
Linker/Locators for Embedded Software, Debugging Techniques.
UNIT-IV: - PIC MICROCONTROLLER AND INTERFACING 12
Introduction- CPU Architecture and Instruction Set- Loop Time Subroutine- Timer2 and Interrupts- Interrupts
Timing- I/O Port Expansion- I2C Bus for Peripheral Chip Access- Analog-to- Digital Converter- UART-
Special Features.
UNIT-V: - EMBEDDED MICROCOMPUTER SYSTEMS 12
ARM 7 Family Architecture - Registers- Addressing Modes. Interfacing Methods: Parallel I/O Interface-
Parallel Port Interfaces- Memory Interfacing- High Speed I/O interfacing-Analog interfacing, Interrupts,
Interrupts Service Routine- Features of Interrupts- Interrupt Vector and Priority, Timing Generation and
Measurements: Input Capture- Output Compare- Frequency Measurement, Serial I/O Devices: RS232-
RS485.
Page 8 of 43
L = 45, T = 15, TOTAL= 60
REFERENCE BOOK
1. David E Simon, An Embedded Software Primer, Pearson Education Asia, 2001
2. John B. Peat man , Design with Microcontroller, Pearson Education Asia, 1998
3. Jonarthan W. Valvano Brooks/Cole ,Embedded Micro Computer Systems, Real Time Interfacing,
Thomson Learning 2001
4. Burns, Alan and Wellings, Andy, Real-Time Systems and Programming Languages, Second Edition,
Harlow: Addison-Wesley-Longman, 1997
5. Raymond J.A. Bhur and Donald L.Bialey, An Introduction to Real Time Systems: Design to
Networking with C/C++, Prentice Hall Inc, New Jersey, 1999
6. Grehan Moore, and Cyliax, Real Time Programming: A Guide to 32 Bit Embedded Development.
Reading: Addison-Wesley-Longman, 1998
7. Heath, Steve, Embedded Systems Design. Newnes , 1997
PPC103 COMMUNICATION PROTOCOLS FOR
INSTRUMENTATION
4 CREDITS
Goal The aim of this course is to give exposure to Hierarchical Structure of networks used in
Automation and Control Systems and Understand the ISO OSI Seven Layer
Communication Structure, Communication interfaces, Ethernet, Communication protocols.
Objectives Outcome
The course should enable the students :
1. To understand the use of Communication
Model for recent Industry Networks.
2. To widen the knowledge on Communication
Protocols.
3. To learn about the Network Architectures.
4. To expand knowledge on Field Bus.
5. To enrich expertise on the commissioning of
Industrial Networks. systems
At the end of the course the student should be able
to:
1. Explain the concept of communication
model, OSI reference model, Recent
Industry networks.
2. Classify the Network selection applicable
for specific industrial needs.
3. Differentiate the Network Architecture and
understand the concepts of Industrial
protocols like Ethernet, Modbus, and
Modbus Plus.
4. Design and install Field Bus oriented
Industrial Communication Networks.
5. Calibrate the smart devices using Profibus
and Field Bus of any Industrial Application
UNIT-I: - INTRODUCTION 12
An Introduction to Networks in process automation: Information flow requirements, Hierarchical
communication model, Data Communication basics, OSI reference model, Industry Network, Recent
networks.
UNIT-II: - COMMUNICATION PROTOCOLS 12
Introduction to Communication Protocols: Communication basics, Network Classification, Device
Networks, Control Networks, Enterprise Networking, Network selection.
UNIT-III: - NETWORK ARCHITECTURES 12
Proprietary and open networks: Network Architectures, Building blocks, Industry open protocols
(RS-232C, RS- 422, and RS-485), Ethernet, Modbus, Modbus Plus, Data Highway Plus, Advantages and
Limitations of Open networks, IEEE 1394.
Page 9 of 43
UNIT-IV: -FIELD BUS 12
Field bus: Field bus Trends, Hardware selection, Field bus design, Installation, Documentation, Field
bus advantages and limitations. HART: Introduction, Design, Installation, calibration, commissioning,
Application in Hazardous and Non-Hazardous area.
UNIT-V: - PLANNING AND COMMISSIONING 12
Foundation Field bus & Profibus: Introduction, Design, Calibration, Commissioning, Application in
Hazardous and Non-Hazardous area. Introduction to wireless Protocols: WPAN, Wi-Fi, Bluetooth, ZigBee,
Z-wave.
L = 45 T = 15 Total = 60
REFERENCE BOOK
1. B.G. Liptak, „Process Software and Digital Networks, CRC Press ISA-, 2002.
2. RomillyBowden,„HART Communications Protocol‟, Fisher-Rosemount, 2003.
3. User Manuals of Foundation Field bus, Profibus, Modbus, Ethernet, Device net, and Control net.
PVL102 Real Time Operating System 4 CREDITS
Goal To develop in-depth skills in Real Time Operating Systems.
Objectives Outcome
The course will enable the students to:
1. Review Operating Systems.
2. Understand about Distributed Operating
Systems.
3. Learn Real Time Models and Languages.
4. Understand about introduction to Real
Time Kernels.
5. Understand about RTOS and Application
Domains.
After completion of the course the students are
expected to :
1. Explain various operating systems
2. Explain Basic building blocks of Real time
Operating Systems.
3. Interface various peripherals to RTOS.
4. Program Real time Systems.
5. Develop Real time Systems.
UNIT-I: -REVIEW OF OPERATING SYSTEMS 12
Basic Principles-system calls-Files-Processes-Design and implementation of processes- Communication
between processes operating system structures.
UNIT-II: - DISTRIBUTED OPERATING SYSTEMS 12
Topology-Network Types-Communication-RPC-Client server model- Distributed file systems.
UNIT- III:-REALTIME MODELS AND LANGUAGES 12
Event based-Process based-Graph models-Petrine tmodels-RTOS tasks-RTOS scheduling– Interrupt
processing-Synchronization-Control blocks-Memory requirements.
UNIT- IV:-REAL TIME KERNEL 12
Principles – Polled loop systems-RTOS porting to a target-Comparison and Study of RTOS– VX Works and
µCoS, Introduction to POSIX and OSEK standards.
UNIT- V:-RTOS AND APPLICATION DOMAINS 12
Page 10 of 43
RTOS for Contro l -Embedded RTOS for Control over IP - RTOS for fault tolerant applications -RTOS for
control systems.
L= 45 T=15 TOTAL=60
REFERENCE BOOK 1. Hermann K, „Real time systems-design principles for distributed embedded Applications’, Kluwer
academic, 1997.
2. CharlesCrowley„operatingsystems-Adesignorientedapproach’McGrawHill,1998
3. AJBUHR, DL Beily, „An i ntroduction to real time systems’PHI, 1999
4. CM Krishna, Kang G. Shin, „Real time Systems’, Mc GrawHill, 1997
5. Raymond J.A., Donald L Baily, „An i ntroduction to real time operating systems’PHI, 1999
PPC104 EMBEDDED SYSTEM DESIGN
LABORATORY
1 CREDITS
Goal The aim of this course is to train students with skills in Designing of Embedded based
systems required for Industrial Automation and Control Systems.
Objectives Outcome
The course should enable the students :
1. To understand the register architecture of
Atmel 8051,PIC 16f877A Microcontroller.
2. To widen the knowledge on interfacing
various serial Communication Protocols.
3. To learn about interfacing various parallel
communication protocols.
4. To expand knowledge on Interfacing Digital
Input and Output.
5. To develop expertise on Interfacing the
Analog input and output.
At the end of the course the student should be
able to: 1. Explain the organization of Registers, Memory
and Instruction set with the knowledge of
Addressing modes which help the student to
develop program sequence for any industrial
application.
2. Communicate with any device using USART
Configurable Communication Interface.
3. Interface the Parallel/Serial LCD Interface and
Alphanumerical Keyboard Interface.
4. Design a complete Data acquisition system with
Analog sensor interface and Digital sensors.
5. Simulate the complete embedded application
using Virtual Simulation Software (Proteus)
LIST OF EXPERIMENTS
1. System Design Study using Atmel, PIC Microcontrollers.
2. System Design for interfacing various parallel communication protocols.
3. System Design for interfacing various serial communication protocols.
4. System Design for Digital Input and Output ( includes Virtual Simulation)
5. System design for Analog input and output. ( includes Virtual Simulation)
P=45 TOTAL=45
Page 11 of 43
SEMESTER II
PPD204 LINEAR AND NON - LINEAR SYSTEM THEORY
Common to M.Tech. (PC&IE) / M.Tech. (EC)/ M.Tech. (PSE) 4 CREDITS
Prerequisite Control Systems
Goal To provide an insight theory on linear and nonlinear control systems.
Objectives Outcome
The course should enable the students to:
1. Study the concept of state space representation of
dynamic systems.
2. Study about solution of state equations of linear,
nonlinear, time invariant and time varying systems
and also about systems modes.
3. Know about the concepts of controllability,
Observability, detectability, stabilizability and
reducibility of time invariant and time varying
systems.
4. Have an in-depth knowledge about stability of linear
and nonlinear systems using Liapunov‟s criterion.
5. Study the concept of observable and controllable
companion forms and pole placement by feedback
for SISO and MIMO systems.
At the end of the course the student should be
able to:
1. Derive state space equations and draw
state diagrams for physical systems
2. Solve state equations of linear, nonlinear,
time invariant and time varying systems,
3. Verify if a given system is controllable,
observable, detectable, stabilizable and
reducible.
4. Verify if a given system is stable using
Liapunov‟s criterion.
5. Develop observable and controllable
companion forms for a given system.
UNIT I STATE VARIABLE REPRESENTATION` 12
Introduction-Concept of State-State equation for Dynamic Systems-Time invariance and linearity-Non
uniqueness of state model-State Diagrams-Physical System and State Assignment.
UNIT II SOLUTION OF STATE EQUATION 12 Existence and uniqueness of solutions to Continuous-time state equations-Solution of Nonlinear and Linear
Time Varying State equations-Evaluation of matrix exponential-System modes-Role of Eigenvalues and
Eigenvectors.
UNIT III CONTROLLABILITY AND OBSERVABILITY 12
Controllability and Observability-Stabilizability and Detectability-Test for Continuous time Systems- Time
varying and Time invariant case-Output Controllability-Reducibility-System Realizations.
UNIT IV STABILITY 12 Introduction-Equilibrium Points-Stability in the sense of Lyapunov-BIBO Stability-Stability of LTI Systems-
Equilibrium Stability of Nonlinear Continuous Time Autonomous Systems-The Direct Method of Lyapunov
and the Linear Continuous-Time Autonomous Systems-Finding Lyapunov Functions for Nonlinear
Continuous Time Autonomous Systems-Krasovskii and Variable-Gradient Method.
UNIT V MODAL CONTROL 12 Introduction-Controllable and Observable Companion Forms-SISO and MIMO Systems-The Effect of State
Feedback on Controllability and Observability-Pole Placement by State Feedback for both SISO and MIMO
Systems-Full Order and Reduced Order Observers.
L = 45 T = 15 Total = 60
Page 12 of 43
REFERENCE BOOK
1. M. Gopal, “Modern Control System Theory”, New Age International, 2005.
2. K. Ogatta, “Modern Control Engineering”, PHI, 2002.
3. John S. Bay, “Fundamentals of Linear State Space Systems”, McGraw-Hill, 1999.
4. D. Roy Choudhury, “Modern Control Systems”, New Age International, 2005.
5. John J. D‟Azzo, C. H. Houpis and S. N. Sheldon, “Linear Control System Analysis and Design with
MATLAB”, Taylor Francis, 2003.
6. Z. Bubnicki,”Modern Control Theory”, Springer, 2005.
PPC201 PROGRAMMABLE LOGIC CONTROLLER &
DISTRIBUTED CONTROL SYSTEMS
4 CREDITS
Goal The goal of the programme is to acquaint the student with basic programming skills of PLC and
DCS so that they will be able get an insight of industrial Process Control scenario.
Objectives Outcome
The course should enable the students :
1. To get a sound knowledge on digital data
acquisition devices and digital controllers.
2. To learn about the basic building blocks of PLC,
basic commands and functions.
3. To know the various functions for programming
PLC
4. To know about the various interfacing devices Bus
Standards to PLC and DCS.
5. To know the basic concepts in DCS
The students should be able to:
1. Design digital acquisition devices and digital
controllers
2. Program PLC for simple applications using
Timers and Counters.
3. Program PLC using Intermediate functions
4. Design interfacing system for PLC and DCS.
5. Understand the architectures of DCS
environment.
Unit I:-Review of computers in process control: 12
Data loggers, Data Acquisition Systems (DAS), Direct Digital Control (DDC). Supervisory Control and Data
Acquisition Systems (SCADA), sampling considerations. Functional block diagram of computer control
systems. Alarms, interrupts. Characteristics of digital data, controller software, linearization. Digital controller
modes: Error, proportional, derivative and composite controller modes.
Unit II: - Programmable logic controller (PLC) basics: 12
Definition, overview of PLC systems, input/output modules, power supplies, isolators. General PLC
programming procedures, programming on-off inputs/ outputs. Auxiliary commands and functions: PLC
Basic Functions: Register basics, timer functions, counter functions.
Unit III:-PLC intermediate functions: 12
Arithmetic functions, number comparison functions, Skip and MCR functions, data move systems. PLC
Advanced intermediate functions: Utilizing digital bits, sequencer functions, matrix functions. PLC Advanced
functions: Alternate programming languages, analog PLC operation, networking of PLC, PLC-PID functions,
PLC installation, troubleshooting and maintenance, design of interlocks and alarms using PLC. Creating
ladder diagrams from process control descriptions.
Unit IV: - Interface and backplane bus standards for instrumentation systems Field bus: 12
Introduction, concept. HART protocol: Method of operation, structure, operating conditions and applications.
Smart transmitters, examples, smart valves and smart actuators.
Unit V: - Distributed control systems (DCS): 12
Definition, Local Control (LCU) architecture, LCU languages, LCU - Process interfacing issues,
communication facilities, configuration of DCS, displays, redundancy concept- case studies in DCS.
Page 13 of 43
L = 45 T = 15 Total = 60
REFERENCE BOOK
1. John. W.Webb Ronald A Reis , Programmable Logic Controllers – Principles and
Applications, Third edition, Prentice Hall Inc., New Jersey, 1995.
2. Lukcas M.P Distributed Control Systems, Van Nostrand Reinhold Co., NewYork, 1986.
3. Deshpande P.B and Ash R.H, Elements of Process Control Applications, ISAPress, New York, 1995.
4. Curtis D. Johnson, Process Control Instrumentation Technology, Fourthedition, Prentice Hall of
India, New Delhi, 1999.
PIA201 ADVANCED CONTROL SYSTEM
4 CREDITS
Goal The goal of the programme is to review Process Modeling and Classical Control Theory
concepts, analyze and design of control schemes in the continuous and discrete-time domain.
Objectives Outcome
The course should enable the students to :
1. Study the linear dynamic models for
advanced control systems
2. Understand the State Space analysis of
continuous time systems.
3. To assist the learners in understanding
Observer design and kalman‟s filtering.
4. To learn the state feedback controller
design methods.
5. To learn the Model Predictive Control.
The students should be able to:
1. Develop a state space model for a given transfer
function and be able to convert into controllable
canonical or observable canonical or diagonal
canonical form.
2. Analyze State Space analysis of continuous time
systems.
3. Design observer for systems and implement kalman
filtering for systems.
4. Provide solutions and design state feedback
controllers.
5. Design and develop Model Predictive Control for
various process systems.
Unit I: Linear Dynamic Models for Advanced Control 12
Dynamic models in chemical engineering and linearization. Linear continuous time state space
models and Laplace Transfer function matrix representation. Computer oriented (or discrete time)
state space models and z-transfer function matrix representation. Development of discrete time state
space models from input-output data (development of OE and ARMAX models, state realizations)
Unit II: Analysis of State Space Models 12
State transformations, poles and zeros, characteristic equation. Solution of unforced and forced
linear differential and difference equations and asymptotic behavior of solutions. Lyapunov stability
analysis.
Unit III: Observer design 12
Observability and observervable canonical form, Luenberger (SISO) observer and pole placement
design, Prediction and current state observer, reduced order observer. Observer design in presence of
state and measurement noise, Kalman filtering and optimal state estimation, convergence of observer
error connection between Kalman filter and linear time series models.
Unit IV: State feedback controller design 12
Page 14 of 43
Controllability, reachability and controllable canonical form. State feedback controller for SISO
systems design by pole placement, difficulties in extending to multivariable systems. Linear
quadratic optimal control (Derivation of Riccati equations, set point tracking and disturbance
rejection, stability analysis). Separation Principle and state feedback control using state observers.
Examples of state LQ and LQG.
Unit V: Model Predictive Control 12
Limitations of LQ control and operating constraints. Dynamic matrix control (state space
formulation, nconstrained solution, QP formulation), Internal Model Control. Model predictive
control (MPC) based on state estimation (Kalman filtering). Nominal stability and robustness of
MPC. MPC case study. Beyond linear multivariable control. L = 45 T = 15 Total = 60
REFERENCE BOOK
1. Astrom, K. J. and B. Wittenmark, Computer Controlled Systems, PrenticeHall, 1990.
2. Franklin, G. F. and J. D. Powell, Digital Control of Dynamic Systems, Addison-Wesley, 1989.
3. Graham C. Goodwin, Stefan F. Graebe, Mario E. Salgado, Control SystemDesign, Prentice Hall,
2000.
PIA202 INTELLIGENT CONTROL 4 CREDITS
Goal Students completing this course will obtain a basic understanding of fuzzy logic systems and
artificial neural networks, and will know how these techniques are applied to engineering
problems, including control systems. Students will understand the advantages and
disadvantages of these methods relative to other control methods. Students will be aware of
current research trends and issues. Students will be able to design control systems using fuzzy
logic and artificial neural networks.
Objectives Outcome
The course should enable the students to :
1. Obtain a basic understanding of fuzzy logic systems
and artificial neural networks.
2. Know how Artificial Neural Network techniques are
applied to engineering problems, including control
systems.
3. Understand Genetic Algorithm methods for solving
control system problems.
4. Able to design control systems using fuzzy logic and
artificial neural networks.
At the end of the course the student should be able
to:
1. Explain the concept of intelligent control and
Expert systems.
2. Classify the various ANN Models and train the
network for control system specific application.
3. Design Fuzzy Logic Controller with Knowledge
based rules and specification.
4. Develop applications using Genetic Algorithm,
Fuzzy Logic, Neural Networks and able to
Model Linear and Non Linear systems using
Matlab.
UNIT I: INTRODUCTION 12
Approaches to intelligent control. Architecture for intelligent control. Symbolic reasoning system,
rule-based systems, the AI approach. Knowledge representation. Expert systems.
UNIT II: ARTIFICIAL NEURAL NETWORKS 12
Concept of Artificial Neural Networks and its basic mathematical model, McCulloch-Pitts neuron
model, simple perceptron, Adaline and Madaline, Feed-forward Multilayer Perceptron. Learning and Training
the neural network. Data Processing: Scaling, Fourier transformation, principal-component analysis and
wavelet transformations. Hopfield network, Self-organizing network and recurrent network. Neural Network
based controller
Page 15 of 43
UNIT III: GENETIC ALGORITHM 12
Basic concept of Genetic algorithm and detail algorithmic steps, adjustment of free parameters.
Solution of typical control problems using genetic algorithm. Concept on some other search techniques like
tabu search and ant-colony search techniques for solving optimization problems.
UNIT IV: - FUZZY LOGIC SYSTEM 12
Introduction to crisp sets and fuzzy sets, basic fuzzy set operation and approximate reasoning.
Introduction to fuzzy logic modelling and control. Fuzzification, inference and defuzzification. Fuzzy
knowledge and rule bases. Fuzzy modelling and control schemes for nonlinear systems. Self-organizing fuzzy
logic control. Fuzzy logic control for nonlinear time-delay system.
UNIT V: - APPLICATIONS 12
GA application to power system optimisation problem, Case studies: Identification and control of
linear and nonlinear dynamic systems using Matlab-Neural Network toolbox. Stability analysis of Neural-
Network interconnection systems. Implementation of fuzzy logic controller using Matlab fuzzy-logic toolbox.
Stability analysis of fuzzy control systems.
L = 45 T = 15 Total = 60
REFERENCE BOOK
1. Jacek.M.Zurada, "Introduction to Artificial Neural Systems", Jaico Publishing House, 1999.
2. Kosko, B. "Neural Networks and Fuzzy Systems", Prentice-Hall of India Pvt. Ltd., 1994.
3. Klir G.J. &Folger T.A. "Fuzzy sets, uncertainty and Information", Prentice-Hall of India Pvt Ltd.,
1993
4. Zimmerman H.J. "Fuzzy set theory-and its Applications"-Kluwer Academic Publishers, 1994.
5. D. Driankov, H. Hellendoorn, M. Rein frank, "Introduction to Fuzzy Control", Narosa Publishers,
2001.
PIA203 INDUSTRIAL AUTOMATION AND ROBOTICS 4 CREDITS
Goal To understand the concepts of automation and the requirement for automation in industries.
They would also understand the basics of robotics and their real time applications.
Objectives Outcome
The course should enable the students to :
1. Understand concepts of Industrial Automation.
2. Understand basics of robotics.
3. Understand various Automation Techniques used in
current scenario.
4. Understand the design and application of robots in
various fields such as industry, defense, etc.
At the end of the course the student should be able
to:
1. Explain the requirements of modern day
industries.
2. Differentiate between high volume
manufacturing automation and flexible
manufacturing.
3. Design robots for industrial applications.
UNIT-I: - Introduction to Automation 12
Automation production system, Mechanization and automation, Types of automation, Automation
strategies, Mechanical, electrical, hydraulic and Pneumatic automation devices and controls,
Economics of automation.
UNIT-II: - High Volume Manufacturing Automation 12
Classification and type of automatic transfer machines; Automation in part handling and feeding,
Analysis of automated flow lines, design of single model, multimodel and mixed model production
lines.
Page 16 of 43
Programmable Manufacturing Automation CNC machine tools, Machining centers,
Programmable robots, Robot time estimation in manufacturing operations.
UNIT-III: - Flexible Manufacturing Automation 12
Introduction to Group Technology, Grouping methods, Cell Design, Flexible manufacturing system.
Assembly Automation: Assembly systems, Automatic transfer, feeding and orienting devices,
Flexible assembly systems, Performance evaluation and economics of assembly systems.
UNIT- IV:- Robotics 12
Review of robotic technology and applications, Laws of robotics, Robot systems and anatomy,
Robot classification, End Effectors, Robot kinematics, Object location, Homogeneous
transformation, Direct and inverse kinematics, Manipulator motions, Robot drives, actuators and
control, Drive systems, Hydraulic, Pneumatic Electrical DC and AC servo motors and stepped
motors, Mechanical transmission method-Rotary-to-rotary motion conversion, Robot motion and
path planning control and Controllers, Robot sensing, Range sensing, Proximity sensing, touch
sensing, Force and torque sensing etc., Robot vision, Image representation, Image recognition
approaches.
UNIT- V:- Robot Applications 12
Robot applications in manufacturing-Material transfer and machine loading/unloading, Processing
operations like Welding & painting, Assembly operations, Inspection automation, Robot cell design
and control, Robot cell layouts-Multiple robots & Machine interference, Economics and social
aspects of robotics. Task Programming, Goals of AI Research, AI Techniques, Robot Intelligence
and Task Planning, Modern Robots, Future Application and Challenges and Case Studies. L = 45 T = 15 Total = 60
REFERENCE BOOK
1. Automation, Production System & Computer Integrated Manufacturing Groover Prentice Hall
India
2. Principles of Automation & Automated Production Process Malov and Ivanov Mir Publication
3. Automation in Production Engineering Oates and Georgy Newness -
4. Stochastic Models of Manufacturing Systems Buzacott& shanty Kumar Prentice Hall India
5. Robotics K.S. Fu, R.C. Gonzalez, C.S.G. Lee McGraw Hill
6. Robotics J.J. Craig Addison-Wesely
7. Robot Engineering: AnIntegrated Approach R.D.Klafter, T.A.Chmielewski and M.Negin,
Prentice Hall India.
PIA204 PROCESS DYNAMICS AND CONTROL 4 CREDITS
Goal
Students completing this course will understand the concepts of Process Modelling, Process
Simulation, various analyses, and physiological models. Students will also have knowledge on
Linear and Non Linear State space modelling and the basics of Process Control and
Instrumentation.
Objectives Outcome
Page 17 of 43
To impart knowledge on.
1. Fundamentals of Process Modeling, their design and
operation.
2. Simulation, analysis and dynamics of reactors.
3. Physiological models and their modeling.
4. State space modeling of linear and nonlinear systems.
5. Process control and instrumentation.
At the end of this course students should have
knowledge in the following. 1. Process modeling fundamentals.
2. Process simulation analysis.
3. Principal Component analysis.
4. Neural networks and fuzzy modeling.
5. Distillation columns and its control.
UNIT-I: - Introduction to Process Modeling 12
Process Modeling Fundamentals, Extended Analysis of Modeling for Process Operation, Design for
Process Modeling and Behavioral Models, Transformation Techniques, Linearization of Model
Equations, Operating Points.
UNIT-II: - Process Simulation 12
Frequency Response Analysis, General Process Behavior, Analysis of a Mixing Process, Dynamics
of Chemical Stirred Tank Reactors, Dynamic Analysis of Tubular Reactors, Dynamic Analysis of
Heat Exchangers, Dynamics of Evaporators and Separators, Dynamic Modeling of Distillation
Columns, Dynamic Analysis of Fermentation Reactors.
UNIT-III: - Introduction to Physiological Models 12
Modeling of Glucose and Insulin Levels, Introduction to Black Box Modeling, Basics of Linear
Algebra, Data Conditioning, Principal Component Analysis, Partial Least Squares, Time-series
Identification.
UNIT-IV: - Discrete Linear and Non-linear State Space Modeling 12
Discrete Linear and Non-linear State Space Modeling, Model Reduction. Neural Networks, Fuzzy
Modeling, Neuro Fuzzy Modeling, Hybrid Models.
UNIT-V: -: Introduction to Process Control and Instrumentation 12
Behavior of Controlled Processes, Design of Control Schemes, Control of Distillation Columns,
Control of a Fluid Catalytic Cracker L = 45 T = 15 Total = 60
REFERENCE BOOK
1. Brian Roffel, Ben Betlem, “Process Dynamics and Control-Modeling for Control and
Prediction”
2. B.W.Bequette, “Process Dynamics – Modeling, Analysis and Simulation”, PHIPE, New Delhi.
3. G.Stephanapoulous, “Chemical process control: An introduction to Theory and Practice”
Prentice Hall of India (P) Ltd., New Delhi, 1995.
4. F.G.Shinsky, “Process Control Systems, Application, Design and Adjustment” 3rd Edition,
Mc.Graw Hill Book Co., New /York, 1988.
PIA211 EXPERT SYSTEMS LABORATORY 1 CREDIT
Goal
To equip students with skills in various packages like MATLAB, LABVIEW, etc. and to
give exposure in PC based Digital control system techniques.
Page 18 of 43
Objectives Outcome
To impart knowledge on.
1. MATLAB software basics.
2. Usage of Fuzzy Logic Toolbox in MATLAB.
3. Usage of Neural Network Toolbox in
MATLAB.
At the end of this course students should have
knowledge in the following.
1. Expertise in MATLAB software.
2. Design of fuzzy logic controller using Fuzzy Logic
Toolbox in MATLAB.
3. Design a self-executable neural classifier using Neural
Network Toolbox in MATLAB.
LIST OF EXPERIMENTS
The following experiments are to be tested using MATLAB toolboxes although Programming
Language is suggested as a better option:
I. MATLAB Fuzzy Logic Toolbox
1. To implement fuzzy set operations
2. To implement fuzzy relational operations.
3. To design and implement fuzzy temperature controller
4. To design and implement Fuzzy Traffic light controller
5. To write and illustrate the concept of Fuzzy C – means Clustering
6. To design a self-executable fuzzy logic controller
II. MATLAB Neural Network Toolbox
7. Write programs to test the learning rules of Hebb, Perceptron, Delta, and Widrow Hoff in
MATLAB learning rule.
8. To implement the Back propagation algorithm
9. To write and test a program for the linear separability of the input domain
10. To write and implement a Hopfield algorithm.
11. To write a program for pattern recognition
12. To design a self-executable neural classifier.
REFERENCE BOOK
1. JyhShing Roger Jang, Chuen-Tsai Sun, EijiMizutani - “Neuro-Fuzzy and Soft Computing: A
Computational Approach to Learning”, Prentice Hall. 1997
2. Chin –Teng Lin and C.S. George Lee - “Neural Fuzzy Systems” – A Neuro fuzzy synergism to
intelligent systems Prentice Hall International. 1996
3. Yanqing Zhang and Abraham Kandel - “Compensatory Genetic Fuzzy Neural Networks
andTheir Applications" World Scientific. 1998
4. S.N. Sivanandam, S. Sumathi, S.N. Deepa Introduction to Neural Networks using Mat Lab6.0 –
Tata Mc Graw Hill 2006. P=45 TOTAL=45
PIA212 INDUSTRIAL AUTOMATION AND ROBOTICS
LABORATORY 1 CREDIT
Goal
To equip students with skills in various packages like MATLAB, LABVIEW, etc. and to give
exposure in PC based Digital control system techniques.
Objectives Outcome
Page 19 of 43
To impart knowledge on.
1. Data Loggers / Data Acquisition
Systems.
2. Interfacing PC with Real-time systems.
3. Position control system.
4. Control of second-order plan using
Micro controllers.
5. Temperature and Level control.
6. Programmable Logic Controllers
forreal-time systems.
7. Modelling of physical systems
At the end of this course students should have knowledge in
the following.
1. Application of Data Loggers / Data Acquisition Systems
in Control Applications. 2. Interfacing a PC with Real-time systems Control.
3. Digital position control system.
4. Digital control of second-order plan using Micro controllers.
5. Digital temperature and level control.
6. Design of Programmable Logic Controllers for real-time
systems.
7. Modelling of physical systems for electrical, hydraulic and
pneumatic systems.
LIST OF EXPERIMENTS
1. Study of Data Loggers / Data Acquisition Systems.
2. Study of Interacting and Non Interacting System (Cascade and ratio controller implementation).
3. Interfacing PC with Real-time systems.
4. Digital position control system.
5. Digital control of second-order plant using Micro controllers.
6. Digital temperature and level control.
7. Design and analysis of second-order systems.
8. Design of Programmable Logic Controllers for real-time systems.
9. Modeling and analysis of basic hydraulic systems using MATLAB/LABVIEW software.
10. Modeling and analysis of basic electrical using MATLAB/LABVIEW software.
11. Modeling and analysis of basic pneumatic systems using MATLAB/LABVIEW software.
P=45 TOTAL=45
SEMESTER III
List of Electives
Elective-I
PIA321 SCADA SYSTEMS AND APPLICATIONS 4 CREDITS
Goal
By completing this course students will have a thorough understanding of SCADA, their
System Components, and various SCADA Architectures. Students will also acquire
knowledge on various applications of SCADA in real time and the basics of Programmable
Automation Controllers. (PAC)
Objectives Outcome
Page 20 of 43
To impart knowledge on.
1. Basics of Data acquisition systems and
evolution of SCADA.
2. SCADA System Components.
3. Various SCADA architectures, their
advantages and disadvantages.
4. SCADA Applications.
5. Programmable Automation Controllers.
At the end of this course students should have knowledge in
the following. 1. Evolution of SCADA and their need in utility automation and
industries.
2. Analysis of the various SCADA System Components.
3. SCADA architectures, SCADA Communication technologies.
4. Practice in simulation exercises to understand the applications
of SCADA.
5. OLE for Process Control, PAC and its architecture using NI
hardware and software.
Unit I Introduction to SCADA 9
Data acquisition systems, Evolution of SCADA, Communication technologies, Monitoring and
supervisory functions, SCADA applications in Utility Automation, Industries
Unit II: SCADA System Components 9
Schemes- Remote Terminal Unit (RTU), Intelligent Electronic Devices (IED), Programmable Logic
Controller (PLC), Communication Network, SCADA Server, SCADA/HMI Systems
Unit III: SCADA Architecture 9
Various SCADA architectures, advantages and disadvantages of each system - single unified
standard architecture -IEC 61850 SCADA Communication: various industrial communication
technologies -wired and wireless methods and fiber optics. Open standard communication protocols
Unit IV: SCADA Applications 9
Utility applications- Transmission and Distribution sector -operations, monitoring, analysis and
improvement. Industries - oil, gas and water. Case studies, Implementation, Simulation Exercises
Unit V: OLE for Process Control& PAC 9
OPC Basics, OPC Standards, Introduction to Programmable Automation Controllers (PAC), PAC
architecture using NI hardware and software L=45 , T 15 TOTAL=60
REFERENCE BOOK
1. Stuart A. Boyer: SCADA-Supervisory Control and Data Acquisition, Instrument Society of
America Publications, USA, 2004.
2. Gordon Clarke, Deon Reynders: Practical Modern SCADA Protocols: DNP3, 60870.5 and
Related Systems, Newnes Publications, Oxford, UK,2004
3. William T. Shaw, Cybersecurity for SCADA systems, Penn Well Books, 2006
4. David Bailey, Edwin Wright, Practical SCADA for industry, Newnes, 2003
5. Michael Wiebe, A guide to utility automation: AMR, SCADA, and IT systems for electric
power.
PIA322 DATA ACQUISITION SYSTEMS
4 CREDITS
Goal
After completing this course, students will understand the objective of a Data Acquisition
System, its types, characteristics, and its principles. Students will also be able to differentiate
between linear and non-linear data converters and its applications.
Page 21 of 43
Objectives Outcome
To impart knowledge on.
1. Single channel and multi-channel DAS and its
components, characteristics.
2. Digital to analog converters (DACS) and Analog
to Digital Converters (ADCS), their classification.
3. Non- linear data converters (NDC), its
configurationand applications.
4. ADC Applications.
5. Monolithic data converters.
At the end of this course students should have
knowledge in the following. 1. Converters and its types, principles, coding and
decoding.
2. Configuration of NDC and data converter
applications.
3. Various industrial applications of ADC.
4. Interfacing of DACS and ADCS to a µP.
5. Error budget of DACS and ADC‟S
UNIT-I 9
INTRODUCTION: Objective of a DAS, single channel DAS, Multi-channel DAS,Components
used in DAS– Converter Characteristics-Resolution-Non-linearity,settling time, Monotonicity.
DIGITAL TO ANALOG CONVERTERS (DACS): Principles and design of – Parallel R– 2R,
Weighted resistor, inverted ladder, D/A decoding – Codes other than ordinary binary.
UNIT-II 9 ANALOG TO DIGITAL CONVERTERS (ADCS): Classification of A/D converters. Parallel
feedback – Successive approximation – Ramp comparison – Dual slope integration – Voltage to
frequency – Voltage to Time – Logarithmic types of ADCS.
UNIT-III 9 NON-LINEAR DATA CONVERTERS (NDC): Basic NDC configurations – Some common
NDACS and NADCS – Programmable non-linear ADCS – NADC using optimal sized ROM – High
speed hybrid NADC – PLS based NADC – Switched capacitor NDCS.
DATA CONVERTER APPLICATIONS: DAC applications – Digitally programmable V/I
sources – Arbitrary waveform generators – Digitally programmable gain amplifiers – Analog
multipliers/ dividers – Analog delay lines.
UNIT-IV 9
ADC APPLICATIONS: Data Acquisition systems – Digital signal processing systems – PCM
voice communication systems – Test and measurement instruments – Electronic weighing machines.
UNIT-V 9
MONOLITHIC DATA CONVERTERS: typical study of monolithic DACS and ADCS.
Interfacing of DACS and ADCS to a microprocessor
Error budget of DACS and ADCS: Error sources, error reduction and noise reduction techniques
in DAS. Error budget analysis of DAS, case study of a DAC and an ADC. L=45 , T 15 TOTAL=60
REFERENCE BOOK
1. Electronic data converters fundamentals and applications – Dinesh K. Anvekar, B.S. Sonde – Tata
McGraw Hill.
Page 22 of 43
2. Electronic Analog/ Digital conversions – Hermann Schmid – Tata McGraw Hill.E.R. Hanateck, User‟s
Handbook of D/A and A/D converters – Wiley
3. Electronic instrumentation by HS Kalsi- TMH 2 nd Edition, 2004.
4. Data converters by G.B. Clayton.
PIA323 ADVANCED SENSOR TECHNOLOGY
4 CREDITS
Goal
After completing this course students will understand about various sensors and their
applications in industry. Students will also be able to design various sensor circuits for
industries.
Objectives Outcome
To impart knowledge on.
1. Chemical sensors and its types.
2. Optical sensors and its types.
3. Biomedical sensors, types and its
applications like ECG, EEG etc.
4. Advanced Sensor design.
5. Aerospace Sensor and its
applications.
At the end of this course students should have knowledge in
the following.
1. Chemical Sensors.
2. Fiber optic light propagation in Optical Sensors.
3. Sensors used in human body, Bioelectric Amplifiers.
4. Various Electrodes, ECG, EEG, electrodes ECG signals,
waveforms.
5. Sensor designing, Fluoroscopic Machines Design.
Unit-I 9
Chemical Sensors: Blood –Gas and Acid –base physiology of electrochemical sensors, Chemical
Fibro sensors, Iron-Selective Field-Effect Transistor (ISFET), Immunologically Sensitive Field
Effect Transistor (IMFET), integrated flow sensor and Blood Glucose sensors.
Unit-II 9
Optical Sensors: Fiber optic light propagation, Graded index fibers, Fiber optic communication
Driver circuits, Laser classifications, Driver circuits for solid –state laser diodes, Radiation sensors
and Optical combinations.
Unit-III 9
Biomedical Sensors: Sensors Terminology in human body, Introduction, Cell, Body Fluids
Musculoskeletal system, Bioelectric Amplifiers, Bioelectric Amplifiers for Multiple Input Circuits,
Differential Amplifiers, Physiological Pressure and other cardiovascular Measurements and devices.
Electrodes: –Electrodes for Biophysical sensing, Electrode model circuits, Microelectrodes, ECG,
EEG, electrodes ECG signals, waveforms, Standard lead system, Polarization, Polarizable, Non
polarizable electrodes and body surface recording electrodes. Ultrasonic Transducers for
Measurement and therapy – radiation detectors – NIR spectroscopy.
Unit-IV 9
Advanced Sensor Design: Fluoroscopic machines design, Nuclear medical systems, EMI to
Biomedical sensors, types and sources of EMI, Fields, EMI effects. Computer systems used in X ray
and Nuclear Medical Equipments. Calibration, Typical faults, Trouble shooting, Maintenance
Procedure for medical equipment‟s and Design of 2& 4 wire transmitters with 4 – 20 mA output.
Unit-V 9
Aerospace Sensor: Gyroscope laser and accelerometers. Sensors used in space and environmental
applications. L=45 , T 15 TOTAL=60
REFERENCE BOOK
1. Sensors Hand Book Sabaree Soloman - Sensors Hand Book, McGraw Hill, 1998
2. Smith H.M. - Principles of Holography, John Wiley & Sons, New York, 1975
3. J.G. Webster Medical instrumentation Application and Design, Houghton Mifilin Co. 2004,
4. Carr and Brown - Introduction to Medical Equipment Technology, Addison Wesley. 1999
Page 23 of 43
5. Culshaw B and Dakin J (Eds) Optical Fibre Sensors, Vol. 1 & 2 Artech House, Norwood.(1989)
P. Garnell– Guided Weapon Control Systems – Pergamon Press. 1980.
Elective-II
PIA324 SYSTEM IDENTIFICATION AND CONTROL 4 CREDITS
Prerequisite Linear and Non linear System Theory
Goal To impart knowledge about system identification techniques and controlling process.
Objectives Outcome
The course will enable the students to :
1. Gain basic knowledge in Process Dynamics
2. Learn about various control strategies for
Process plant.
3. Understand the various methods used for Process
Identification
4. Learn the various techniques used for process
activation.
5. Setup virtual control system environment
The students should be able to:
1. Derive mathematical Model of the Systems.
2. Implement Controllers for Various control systems.
3. Identify the systems of various continuous and
discrete process
4. Implement various process activation techniques for
process
5. Realize and deploy virtual control system
Unit I: 9
Basics of Process Dynamics: - Mathematical Representations of Linear Processes, Simulations,
Dynamic Behavior of Linear Processes
Unit II: 9
Process Control: - Proportional–Integral–Derivative Control, Proportional–Integral–Derivative
Controller Tuning, Dynamic Behavior of Closed-Loop Control Systems, Enhanced Control
Strategies- Cascade Control- Time-Delay Compensators- Gain Scheduling-Proportional–Integral–
Derivative Control using Internal Feedback Loop.
Unit III: 9
Process Identification:- Process Identification Methods for Frequency Response Models, Process
Identification Methods for Continuous-Time Differential Equation Models, Process Identification
Methods for Discrete-Time Difference Equation Models, Model Conversion from Discrete-Time to
Continuous-Time Linear Models.
Unit IV: 9
Process Activation: - Relay Feedback Methods- Conventional Relay Feedback Methods- Relay
Feedback Method to Reject Static Disturbances-Relay Feedback Method under Nonlinearity and
Static Disturbances-Relay Feedback Method for a Large Range of Operation Problems,
Modifications of Relay Feedback Methods- Process Activation Method Using Pulse Signals-Process
Activation Method Using Sine Signals Problem.
Unit V: 9
Virtual Control System: - Setup of the Virtual Control System, Case studies L=45 , T 15 TOTAL=60
REFERENCE BOOK
1. Su Whan Sung, Jietae Lee, In-Beum Lee- Process Identification and PID Control-Jhon Wiley
and sons.
Page 24 of 43
2. Banks J, Carson J.S and Nelson B Discrete Event system Simulation, (2e) prentice hall, 1996.
3. Edwards D and Hamson M Guide to mathematical Modelling, Macmillan, London-1989.
4. Giordano F.R and Weir MDA first course in mathematical modeling, Wadsworth-1985.
5. Deo N System‟s simulation with digital compute Prentice Hall-1983.
PIA325 MULTI-VARIABLE CONTROL 4CREDITS
Goal To provide basic knowledge about various Controllers, Observers and Solutions to their
objective Problems
Objectives Outcome
The course will enable the students :
1. To impart knowledge about the various process
variables, types of models and its equivalence.
2. Emphasis on Linear Systems, Its Time Response,
Frequency Response and Stability Conditions.
3. To acquire knowledge in decentralised and decoupled
Control.
4. To acquaint them with various Controllers and
Observers and their modelling with solutions to their
objective problems.
The students should be able to:
1. Understand the basic principles of Models
and its Representations.
2. Analyse the Linear Systems and
Discretization Techniques.
3. Understand the various types of decentralised
and decoupled control
4. Design an optimal State Feedback Controller,
Kalman observer and understand
Optimisation based Control.
UNIT-I: - LINEAR SYSTEM REPRESENTATION: MODELS AND EQUIVALENCE 9
Introduction, Process Instrumentation, Process Variables, Types of Models, Input/output Representations,
Systems and Subsystems: Interconnection, Equivalence of Representations, Key issues in Modeling
UNIT-II: - LINEAR SYSTEM ANALYSIS 9
Introduction, Linear-System Time Response, Stability Conditions, Discretization, Gain, Frequency
Response, System internal Structure, Block System Structure: Kalman Form, Input/output Properties, Model
Reduction, key issues in MIMO Systems Analysis
UNIT-III: - SOLUTIONS TO THE CONTROL PROBLEM 9
The Control Design Problem, Control Goals, Variables Selection, Control Structures, Feedback
Control, Closed-loop stability analysis, Feed forward control, Two degree of freedom controller, hierarchical
control, key issues in control design
UNIT-IV: - DECENTRALISED AND DECOUPLED CONTROL 9
Introduction, multi-loop control, Pairing Selection, The Relative Gain Array Methodology, Decoupling,
Enhancing SISO Loops with MIMO Techniques: Cascade Control, Other possibilities, Sequential-
Hierarchical Design and Tuning
UNIT-V: - OPTIMISATION BASED CONTROL 9
Optimal State Feedback, Kalman Observer, Linear Quadratic Gaussian Control, Predictive Control,
Distribution Rejection, A Generalized Optimal Disturbance-rejection Problem, Distillation Column: Case
Study
L=45 , T 15 TOTAL=60
REFERENCE BOOK
1. Multivariable Control Systems: An Engineering Approach by P. Albertos, A. Sal, Springer-
Verlag London Limited, 2004
2. Multivariable Feedback design by Maciejowski J.M., published by Adison-Wesley
3. Multivariable Feedback Control by Sigurd Stogestad and Ian Postletwaite, published
by Wiely.
Page 25 of 43
4. Control Configuration Selection in Multivariable Plants by A. Khaki-Sedigh, B. Moaveni,
published by Springer Verlag, 2009.
PIA326 FAULT DETECTION AND DIAGNOSIS 4 CREDITS
Prerequisite Linear and Non-linear System Theory
Goal To impart basic knowledge in fault detection and diagnosis in process plant
Objectives Outcome
The course will enable the students to :
1. Gain basic knowledge about faults and
diagnosis occurring in process plants
2. Know the various methods used for system
identification
3. Understand the Pattern recognition methods for
fault diagnosis.
4. Realize Fault diagnosis advanced techniques
based on process state estimation
5. Work on Artificial neural networks for fault
diagnosis
The students should be able to:
1. Analyze faults and diagnosis occurring in process
plants.
2. Identify systems based on various methods.
3. Develop and implement Pattern recognition methods
for fault diagnosis.
4. Analyze Fault and diagnose themusing advanced
techniques based on process state estimation
5. Implement Artificial neural networks for fault
diagnosis
Unit I: - Basic concepts: - 9
The concept of system analysis -- Basic concepts in fault diagnosis --Fault diagnosis methods
classification ---Elementary functions and performance criteria for the fault diagnosis systems --
Fault diagnosis based on process parameters: Problem formulation -Usual parametric methods --
Relations between process parameters and model parameters
Unit II. Continuous-time system identification methods 9
Problem formulation --State-space variables filtering method --Poisson function moments method --
Piece-wise orthogonal function (Walsh) method --Usual numerical techniques: leas-squares method
and total least-squares method (on- and off-line variants)
Unit III. Pattern recognition methods for fault diagnosis. 9
Basic concepts in pattern recognition --Fundamental principles of the statistic pattern recognition --
Clustering and pattern recognition nonparametric techniques --Particularities of the pattern
recognition -- principles applied to fault diagnosis Fault diagnosis based on process state estimation-
- fundamental principles. The main concept of the fault detection and isolation based on state
estimators (observers) -Linear observers for fault diagnosis: complete order observers, reduced order
-- observers, sensor and -- component fault detection observer schemes -- Nonlinear observers for
fault diagnosis
Unit IV. Fault diagnosis advanced techniques based on process state estimation 9
Unknown inputs robust fault diagnosis –linear systems case --Observers for robust fault diagnosis
Observers for robust fault diagnosis design: observable canonical form, the robust observer design
based on the observable canonical form, optimal robust observers design
Unit V Artificial neural networks for fault diagnosis. 9
Basic concepts on Artificial Neural Networks (ANN) ANN architectures: Multi-Layer Perceptron,
Radial-Basis Functions Networks --ANN training: back-propagation algorithm, orthogonal least-
Page 26 of 43
squares algorithm --Fault diagnosis using ANNs: ANNs used for symptom generation, ANNs used
for symptom evaluation. L=45 , T 15 TOTAL=60
REFERENCE BOOK
1. Isermann, R., (2006), Fault-Diagnosis Systems, Springer-Verlag, Berlin.
2. Chen,J. and R.J.Patton, (1999), Robust Model-based Fault Diagnosis for Dynamic
Systems, Kluwer Academic Publ., Boston.
3. R.J.Patton, P.M.Frank, R.N.Clark (Eds), (2000), Issues in Fault Diagnosis for Dynamic
Systems, Springer-Verlag, New York.
4. Blanke, M., M. Kinnaert, J. Lunze, M. Staroswiecki, (2006), Diagnosis and Fault Tolerant
Control, Springer-Verlag, Berlin.
Page 27 of 43
Elective-III
PIA327 COMPUTER CONTROL OF MANUFACTURING SYSTEMS 4 CREDITS
Goal To acquaint the students with concepts in manufacturing systems
Objectives Outcome
The course should enable the students to:
1. Gain basic concepts in manufacturing
systems
2. Understand control loops and adaptive
schemes for NC machines
3. Acquaint concepts and digitization of CNC
4. Gain knowledge about CIM
5. Know the basics of Flexible manufacturing
systems
At the end of the course the student should be able
to:
1. Analyse manufacturing systems and their
functionality.
2. Realize various control loops and adaptive
schemes related NC machines
3. Acquire and analyze systems of CNC
4. Analyze CIM and its data related systems
5. Deploy and verification of functionality of
Flexible manufacturing systems
Unit I: -Basic concepts in Manufacturing Systems 9
Introduction Basic concepts in Manufacturing Systems, Fundamentals of Numerical Control,
Advantages of NC systems, Classification of NC Systems. Interpolators for manufacturing systems
DDA Integrator, DDA Hardware Interpolator, CNC software Interpolators, Reference word CNC
interpolators, the concept of reference word interpolators. Tusten Method.
Unit II: -Control Loops of NC Systems: 9
Introduction, Control of Point-to-point Systems, Control loops in Contouring Systems, Mathematical
Analysis and operation of a two axis system. Adaptive Control Systems: Introduction, Adaptive
control with optimization, Adaptive control with Constraints. ACC for turning, Variable Gain AC
systems Adaptive control for grinding, Cost analysis in machining.
Unit III: - Manufacturing system simulation: 9
Introduction, Types of simulation, Need and elements of simulation, Simulation methodology.
Computerized Numerical Control: CNC Concepts, Advantages, The Digital Computer, Reference
Pulse Technique, Sampled-Data Technique, Design Principles, Optimization for Circular Motion,
summary of design considerations, micro computers in CNC.
Unit IV: -Computer integrated Manufacturing systems 9
Computer integrated Manufacturing systems Introduction, Modern manufacturing, Sequence of
Functions in CIM, Elements of CIM system, CIM data base management system, CIM related
standards, Guide lines for CIM development Benefits of CIM.
Unit V: -Flexible manufacturing systems 9
Flexible manufacturing systems Introduction, Elements of FMS, Classification and Types of FMS,
FMS work stations, Lay out configurations, Petrinets , modeling with Pertinets. L=45 , T 15 TOTAL=60
REFERENCE BOOK
1. Computer control of manufacturing systems - YoremKoren, Tata McGraw-Hill edition, 2005.
2. Computer Aided Design and Manufacturing - Dr.Sadhusingh, Khanna Publishers, 2002
3. Simulation modeling and Analysis - Averill M Law, TMH, 2008.
Page 28 of 43
PIA328 MECHATRONICS IN MANUFACTURING SYSTEMS 4 CREDITS
Goal
To impart knowledge in the inter disciplinary field of Mechatronics as related to
Manufacturing.
Objectives Outcome
The course should enable the student to
1. Gain basic knowledge in Mechatronic
systems.
2. Know the various types of sensors and
selection procedures.
3. Learn about the types of actuators used in
Mechatronic systems.
4. Understand the operation of Programmable
Logic Controllers.
5. Have an idea mechatronic systems applied
in practical situation.
The students should be able to:
1. Develop an interdisciplinary understanding and
integrated approach to engineering.
2. Select sensor for various applications
3. Acquaint themselves with actuators used in
Mechatronic systems.
4. Deploy Programmable Logic Controllers for
various applications.
5. Understand the real time applications and Develope
them.
UNIT I INTRODUCTION 6
Introduction to Mechatronics - Systems- Need for Mechatronics - Emerging area of Mechatronics -
Classification of Mechatronics - Measurement Systems – Control Systems.
UNIT II SENSORS AND TRANSDUCERS 9
Introduction - Performance Terminology – Potentiometers - LVDT – Capacitance sensors - Strain
gauges - Eddy current sensor - Hall Effect sensor – Temperature sensors - Light sensors - Selection
of sensors - Signal processing.
UNIT III ACTUATORS 12
Actuators – Mechanical - Electrical - Fluid Power - Piezoelectric – Magnetostrictive - Shape
memory alloy - applications - selection of actuators.
UNIT IV PROGRAMMABLE LOGIC CONTROLLERS 9
Introduction - Basic structure - Input and output processing - Programming -Mnemonics- Timers,
counters and internal relays - Data handling - Selection of PLC.
UNIT V DESIGN AND MECHATRONICS CASE STUDIES 9
Designing - Possible design solutions-Traditional and Mechatronics design concepts- Case studies of
Mechatronics systems - Pick and place Robot - Conveyor based material handling system - PC based
CNC drilling machine – Mechatronics Control in automated Manufacturing – Data Acquisition Case
studies. L=45 , T 15 TOTAL=60
REFERENCE BOOK
1. Bolton.W, “Mechatronics”, Pearson education, second edition, fifth Indian Reprint, 2003
2. Smaili.A and Mrad.F, "Mechatronics integrated technologies for intelligent machines", Oxford
university press, 2008.
Page 29 of 43
3. Devadas Shetty and Richard A.Kolk, “Mechatronics systems design”, PWS Publishing
Company, 2007.
4. Godfrey C. Onwubolu, "Mechatronics Principles and Applications", Elsevier, 2006.
5. NitaigourPremchandMahalik, “Mechatronics Principles, Concepts and applications” Tata
McGraw-Hill Publishing Company Limited, 2003.
6. Michael B.Histand and Davis G.Alciatore,”Introduction to Mechatronics and Measurement
systems”. McGraw Hill International edition, 1999.
7. Bradley D.A, Dawson.D, Buru N.C and Loader A.J, “Mechatronics” Nelson Thornes Ltd, Eswar
press, Indian print, 2004.
PIA329 PROCESS CONSULTING AND PROJECT PLANNING
4 CREDITS
Goal
To expose the students to the basic processing, measurement techniques and control systems
in petroleum industry and to provide adequate knowledge about the petroleum products and
the chemicals obtained from them.
Objectives Outcome The course will enable the students to :
1. Develop the knowledge in the direction of
cumulative project engineering.
2. Gather all knowledge required in project
planning, execution and monitoring.
3. Acquaint them with documentation in
process engineering.
4. Gain skills in procurement and functional
verification of process Systems.
5. Gather knowledge about management
functions and tools used for doing it.
After completion of the course the students are
expected to be able to:
1. Develop and deploy the cumulative engineering
projects.
2. Understand and accomplish project planning,
execution and monitoring.
3. Complete the documentation work for projects.
4. Develop interpersonal skills in procurement and
functional verification of process Systems.
5. Use Management tools for various management
related function of a project.
UNIT- I: - Introduction 9
Definition of project, purpose, scope, time, quality and organization structure. Basic and detailed
engineering: Degree of automation, Project S curves, manpower considerations, inter-department
and inter organization interactions, Multi agency interaction. Types of projects and types of contracts
e.g. EPC, BOOT etc.
UNIT-II: -Project Pre-planning steps 9
Role of Automation, Customer expectations and performance criterion, User Requirement
Specifications (URS), Functional Design Specifications (FDS), Software Requirement Specifications
and Hardware Requirement Specifications (SRS and HRS), International Standards and Practices,
Consultant Requirements. Project execution steps. Instrumentation Audit, Plant layout, general
arrangement drawing (plans and elevations). Selection criterion for equipment at different levels of
automation.
UNIT- III Project Documentation 9
Design Engineering, documentation, Process function diagrams and interlock, interface diagrams,
Process flow diagrams, P&ID, specification sheets, loop wiring diagrams, ladder diagrams,
isometrics, installation detail drawing, Control console, centers and panels: Types, design, inspection
and specification. Control panel drawings, Document control, Checklists, legend sheets, instrument
catalogues, test and progress reports, and minutes of the meeting. Documentation software to create
modifies, add, revise and update I&C documentation. Documents and version control Cable
Page 30 of 43
engineering, different classes of conductors and their routines, types and specifications of cables,
cable schedule, routing of cables.
UNIT- IV: -Procurement activities 9
Vendor registration, tendering and bidding process, bid evaluation, purchase orders, vendor
documents, drawings and reports as necessary at above activities. Construction activities: Site
conditions and planning, front availability, installation and commissioning activities and documents
require/generated at this stage. Factory Acceptance Test (FAT), On-site inspection and testing (SAT)
installation sketches, bill of material, Quantity surveying, contracting, cold commissioning and hot
Commissioning, CAT (Customer Acceptance Test), performance trials and final hand-over.
UNIT -V: - Project management: Management functions 9
Controlling, directing, project authority, responsibility, accountability, interpersonal influences and
standard communication formats, project reviews. Project planning and scheduling, life cycle
phases, the statement of work (SOW), projects specifications, bar charts, milestones, schedules,
work breakdown structures, cost breakdown structures and planning cycle. Cost and estimation:
Types and estimates, pricing process, salary and other overheads, man-hours, materials and support
costs. Program evaluation and review techniques (PERT) and critical path method (CPM),
estimating activity time and total program time, total PERT/CPM planning crash times, software‟s
used in project management.
L=45 , T 15 TOTAL=60
REFERENCE BOOK
1. Applied instrumentation in process industries Andrew and Williams Gulf publishing
2. Instrumentation Engineers Handbook: Process Control B. G. Liptak Chilton Book Company
3. Project management: A systems approach to planning Scheduling and Controlling
HarlodKerzner Van Nostrand Reinhold publishing
4. Management systems John Bacon ISA
5. Batch control systems T.G.Fisher ISA
6. Instrument installation project management Reference Set,ISA.
PIA330 ADVANCED ADAPTIVE CONTROL SYSTEMS 4 Credits
GOAL: - To get fundamental idea on advanced Adaptive Control Systems
OBJECTIVES
To introduce various model structures for system identification
To impart knowledge on parametric and non-parametric identification
To introduce non-linear identification techniques
To introduce the concept of adaptation techniques and control
To illustrate the identification and adaptive control techniques through case
Studies
OUTCOMES
To get knowledge about different models
Able to design parametric and non-parametric models
To get idea of non-linear techniques
Will be able design different adaptation control techniques
Will be able to apply adaptive control techniques through case studies
Page 31 of 43
UNIT I MODELS FOR INDENTIFICATION 9
Models of LTI systems: Linear Models-State space Models-OE model- Model sets, Structures and
Identifiability- Models for Time-varying and Non-linear systems: Models with Nonlinearities – Non-
linear state-space models-Black box models, Fuzzy models‟.
UNIT II NON-PARAMETRIC AND PARAMETRIC IDENTIFICATON 9
Transient response and Correlation Analysis – Frequency response analysis – Spectral Analysis –
Least Square – Recursive Least Square –Forgetting factor- Maximum Likelihood – Instrumental
Variable methods.
UNIT III NON-LINEAR IDENTIFICATION 9
Open and closed loop identification: Approaches – Direct and indirect identification –Joint input-
output identification – Non-linear system identification – Wiener models –Power series expansions -
State estimation techniques – Non-linear identification using Neural Network and Fuzzy Logic.
UNIT IV ADAPTIVE COTROL AND ADAPTATION TECHNIQUES 9
Introduction – Uses – Auto tuning – Self Tuning Regulators (STR) – Model Reference Adaptive
Control (MRAC) – Types of STR and MRAC – Different approaches to self-tuning regulators –
Stochastic Adaptive control – Gain Scheduling.
UNIT V CASE STUDIES 9
Inverted Pendulum, Robot arm, process control application: heat exchanger, Distillation column,
application to power system, Ship steering control.
L=45 , T 15 TOTAL=60
REFERENCES
1. Ljung,” System Identification Theory for the User”, PHI, 1987.
2. Torsten Soderstrom, Petre Stoica, “System Identification”, prentice Hall
International (UK) Ltd, 1989.
3. Astrom and Wittenmark,” Adaptive Control”, PHI
4. William S. Levine, “Control Hand Book”. Narendra and Annasamy,” Stable Adaptive
Control Systems, Prentice Hall, 1989.
PIA305 Project Phase-I 6 CREDITS
Goal To enable the students to successfully initiate to implement the design and integrate various
components and circuits that they have learned throughout their course work
Objectives Outcome
Page 32 of 43
The course will enable the students to:
(i) Build circuits for the design considerations (ii) Develop a PC or Microprocessor based system design (iii) Troubleshoot and diagnose various faults occurring
the circuits and software integration
After completion of the course the students are expected
to be able to:
(i) Design circuits for given specification
(ii) Integrate various sensors and final control elements to
a controller and perform necessary control actions
(iii) Troubleshoot electronic circuit or software program
Guidelines & Evaluation Scheme
Each of the students has to undertake a Project under the supervision of a teacher (max 4 students /
batch) and to submit the same following the guidelines stated below.
Language of Project Report and Viva-Voce Examination may be English
Failure to submit the Project Report or failure to appear at the Viva-voce Examination will be treated
as “Absent” in the Examination. He /she has to submit the Project Report and appear at the Viva-
Voce Examination in the subsequent years (within the time period as per University Rules).
No marks will be allotted on the Project Report unless a candidate appears at the Viva-Voce
Examination. Similarly, no marks will be allotted on Viva-Voce Examination unless a candidate
submits his/her Project Report.
Evaluation of the Project Work to be done jointly by one internal expert and one external expert with
equal weightage, i.e., average marks of the internal and external experts will be allotted to the
candidate.
A candidate has to qualify in the Project Work separately, obtaining a minimum marks of 50 (Project
Report and Viva-Voce taken together).
Marking Scheme for Project Report and Viva-Voce Examination:
Project Report (50 marks)
Chapter 1: Introduction – 10 marks
Chapter 2: Conceptual Framework/ National/International Scenario – 5 marks
Chapter 3: Presentation, Analysis & Findings -- 25 marks
Chapter 4: Conclusion & Recommendations -- 10 marks
Viva-Voce (50 marks)
In course of Viva-Voce Examination, the question may be asked in the following
areas:
Importance / relevance of the Study, Objective of the Study, Methodology of the
Study / Mode of Enquiry -- 15 marks
Ability to explain the analysis, findings, concluding observations, recommendation,
limitations of the Study -- 25 marks
Overall Impression (including Communication Skill) -- 10 marks
THE COMPONENTS OF A PROJECT REPORT
The outcome of Project Work is the Project Report. A project report should have the following components:
1) Cover Page: This should contain the title of the project proposal, to whom it is submitted, for which
degree, the name of the author, name of the supervisor, year of submission of the project work, name of the
University.
Page 33 of 43
2) Acknowledgement: Various organizations and individuals who might have provided assistance /co-
operation during the process of carrying out the study.
3) Table of Content: Page-wise listing of the main contents in the report, i.e., different Chapters and its main
Sections along with their page numbers.
4) Body of the Report: The body of the report should have these four logical divisions
a) Introduction: This will cover the background, rationale/ need / justification, brief review of literature,
objectives, methodology (the area of the study, sample, type of study, tools for data collection, and method of
analysis), Limitations of the Study, and Chapter Planning.
b) Conceptual Framework / National and International Scenario: (relating to the topic of the Project).
c) Presentation of Data,Analysis and Findings:(using the tools and techniques mentioned in the
methodology).
d) Conclusion and Recommendations: In this section, the concluding observations based on the main
findings and suggestions are to be provided.
5) Bibliography or References: This section will include the list of books and articles which have been used
in the project work, and in writing a project report.
6) Annexures: Questionnaires (if any), relevant reports, etc.
(The main text of the Project should normally be in the range of 5000 words. However, there may be
annexure in addition to the main text)
SEMESTER IV
PIA406 Project Phase-II 12 CREDITS
Goal To enable the students to successfully design and integrate various components and circuits that they
have learned throughout their course work
Objectives Outcome
The course will enable the students to:
(iv) Build circuits for the design considerations (v) Develop a PC or Microprocessor based system design (vi) Troubleshoot and diagnose various faults occurring
the circuits and software integration
After completion of the course the students are expected
to be able to:
(iv) Design circuits for given specification
(v) Integrate various sensors and final control elements to
a controller and perform necessary control actions
(vi) Troubleshoot electronic circuit or software program
Guidelines & Evaluation Scheme
Each of the students has to undertake a Project under the supervision of a teacher (max 4 students /
batch) and to submit the same following the guidelines stated below.
Language of Project Report and Viva-Voce Examination may be English
Failure to submit the Project Report or failure to appear at the Viva-voce Examination will be treated
as “Absent” in the Examination. He /she has to submit the Project Report and appear at the Viva-
Voce Examination in the subsequent years (within the time period as per University Rules).
Page 34 of 43
No marks will be allotted on the Project Report unless a candidate appears at the Viva-Voce
Examination. Similarly, no marks will be allotted on Viva-Voce Examination unless a candidate
submits his/her Project Report.
Evaluation of the Project Work to be done jointly by one internal expert and one external expert with
equal weightage, i.e., average marks of the internal and external experts will be allotted to the
candidate.
A candidate has to qualify in the Project Work separately, obtaining a minimum marks of 50 (Project
Report and Viva-Voce taken together).
Marking Scheme for Project Report and Viva-Voce Examination:
Project Report (50 marks)
Chapter 1: Introduction – 10 marks
Chapter 2: Conceptual Framework/ National/International Scenario – 5 marks
Chapter 3: Presentation, Analysis & Findings -- 25 marks
Chapter 4: Conclusion & Recommendations -- 10 marks
Viva-Voce (50 marks)
In course of Viva-Voce Examination, the question may be asked in the following
areas:
Importance / relevance of the Study, Objective of the Study, Methodology of the
Study / Mode of Enquiry -- 15 marks
Ability to explain the analysis, findings, concluding observations, recommendation,
limitations of the Study -- 25 marks
Overall Impression (including Communication Skill) -- 10 marks
THE COMPONENTS OF A PROJECT REPORT
The outcome of Project Work is the Project Report. A project report should have the following components:
1) Cover Page: This should contain the title of the project proposal, to whom it is submitted, for which
degree, the name of the author, name of the supervisor, year of submission of the project work, name of the
University.
2) Acknowledgement: Various organizations and individuals who might have provided assistance /co-
operation during the process of carrying out the study.
3) Table of Content: Page-wise listing of the main contents in the report, i.e., different Chapters and its main
Sections along with their page numbers.
4) Body of the Report: The body of the report should have these four logical divisions
a) Introduction: This will cover the background, rationale/ need / justification, brief review of literature,
objectives, methodology (the area of the study, sample, type of study, tools for data collection, and method of
analysis), Limitations of the Study, and Chapter Planning.
b) Conceptual Framework / National and International Scenario: (relating to the topic of the Project).
c) Presentation of Data,Analysis and Findings:(using the tools and techniques mentioned in the
methodology).
d) Conclusion and Recommendations: In this section, the concluding observations based on the main
findings and suggestions are to be provided.
Page 35 of 43
5) Bibliography or References: This section will include the list of books and articles which have been used
in the project work, and in writing a project report.
6) Annexures: Questionnaires (if any), relevant reports, etc.
(The main text of the Project should normally be in the range of 5000 words. However, there may be
annexure in addition to the main text)